Positional data transmitting system



m/vzuroe Q ZMM ATTORNEYS Aug. 3, 1954 Y M. K. TAYQLIOR POSITIQNAL DATA TRANSMITTING SYSTEM Filed Dec. 13, 1951 w 4 Shee ts-Shee t 1 Il I!!! n v w w g H I I l I I l 1954 M. K. TAYLOR 2,685,611

' POSITIONAL DATA TRANSMITTING SYSTEM Y Filed Dec. '15, 1951 f 4 Sheets-Sheet s Fig.5;

Y DECODER X DECODER r INVENTOE vhwni mfd en BY A TTORNE Y Aug. 3, 1954 M. K. TAYLOR 2,685,611

. POSITIONAL DATA TRANSMITTING SYSTEM Fi led Dec. '15, 1951 4 Sheets-Sheet 4 ATTORNEYS Patented Aug. 3, 1954 UNITED STAT OFFICE POSITIONAL DATA TRANSMITTING SYSTEM Application December 13, 1951, Serial No. 261,523

Claims priority, application Great Britain December 15, 1950 11 Claims.

This invention relates to positional data transmitting systems and specifically to systems for transmitting to some distant place data indicating the position of an object with respect to a predetermined reference system comprising two intersecting families of curves. The term curve is to be understood hereinafter to include, where appropriate, the special case of a straight line. In addition, it is to be understood that the curves of a family of curves need not be co-planar.

Such a reference system may, for example, be a map grid or other form of rectangular co-ordinates, each family of curves in this instance comprising a set of parallel straight lines and the various points of intersection lying in a common plane. In another form the reference system may consist of representations of latitude and longitude, the curves, in this instance, being circles disposed upon the surface of a common sphere and on which surface the various points of intersection will lie. In yet another form the reference system may be one of polar coordinates, one family of curves being co-planar concentric circles and the other being (to-planar straight lines passing through a common'origin lying at the centre of such circles. The invention may also be used in conjunction with one of the well known kinds of hyperbolic navigational systems, eachfamily of curves then being a set of confocal hyperbola-s.

An object of the present invention is to provide an improved positional data transmitting system for the purpose stated.

Another object of the present invention is to provide a system for transmitting data indicative of the position of an object with respect to a predetermined reference system of two intersecting families of curves and comprising two sets of transmitter electrical conductors, such cnductors being shaped and positioned to represent respectively the afoersaid two families of curves and each conductor being insulated from all other conductors, for each of said transmitter conductors a corresponding receiver conductor, contact for effecting at any given moment electrical connection with one transmitter conductor in each of said sets of transmitter conductors, which connected conductors are repre sentative of those twoof said curves whose intersection defines the position of saidobject at that ductor, decoding means for causing each of said signals to energize the particular receiver (30ndifferent values of Y.

ductor corresponding to the transmitter conductor which is represented by that signal and reproducing means whereby .the energization of said two receiver conductors results in the indication of the position of said object.

The two sets of conductors above referred to may be so located relative to each other as to form a grid-like assembly of conductors. Alternatively, such sets of conductors may be separated irom each other. The aforesaid contact means may be arranged to connect the said two conductors in series or in parallel thereby completing an electric circuit of which each of said two conductors forms a part, or two electric circuits of which said conductors respectively form parts, as the case may be.

In order that the various objects and features of the invention may be more readily understood embodiments of the inventionwill now be described in greater detail and with reference to the accompanying drawings wherein:

Fig. 1 is an exploded perspective view of one form of transmitter device.

Figs. 2 and 3 are side and end elevational views of the device of Fig. 1. V

Fig. 4 is a, schematic circuit diagram illustrating the coding arrangements at the transmitter.

Fig. 5 is a perspective View of one form of receiver device.

Fig. 6 is a schematic view illustrating one form of receiver decoding device.

Figs. 7, 8 and 9 are-schematic diagrams illustrating alternative forms of transmitter device.

' The invention will first be described, by way of example, for use in the simpler case where the predetermined reference system is a, plain rectangular grid and where, accordingly. the data to be transmitted are the rectangular co-ordinates rs and y of the object with respect to such system. In carrying out the invention according to this form thereof, and as shown in Figs. 1, 2 and 3, the transmitted device comprises a rec-- tangularsheet of insulating material lil suitably mounted upon stationary support members i i.

In one face i2 of this'sheet, partially embedded in vertical grooves l3, are disposed a set of straight electrical conductor rods it normal to the X axis. These conductors will hereinafter be referred to as the X- conductorssinoe each one rep-resents a constant value of X for In the other face E5 of the sheet I63 and partially embedded in similar but horizontal grooves it are disposed another set of straight conductor rods l1 normal to the Y axis, i. eat right angles to the X conductors It. These further conductor rods'will, for similar reasons, hereinafter be referred to as the Y conductors. Each conductor M or ll extends the full width or length, as the case may be, of the rectangular field it of the reference system and is sufficiently spaced from its neighboring conductors on the same side of the sheet Hi as to be reliably insulated from them. The sheet ii! is of sufficient thickness to insulate all the conductors it on one face from all the conductors l! on the other face. Although with such aconstruction the two sets of conductors M and H are not actually in the same plane they never theless form effectively a grid-like assembly of conductors and represent respectively the two families of curves that constitute the reference system. This illustrated example is one where the term curve has the special meaning of a straight line.

The various vertical or X conductors M cooperate with a single movable contact 19 which is carried by arms 29, 29 forming part of a pantograph lever system 22 permitting displacement of the contact !9 to any point within the rectangular field l8 so as to make electrical connection with the exposed surface of any chosen one of such X conductors I4 at any given position along its length. The horizontal Y conductors llsimilarly co-operate with a further movable contact 23 which is carried by lever arms 2%, also forming part of the pantograph lever system 2 2'. This contact 23' is capable of movement to any point within the same rectangular field it so as to make electrical connection with the exposed surface of any chosen one of the Y conductors H at any given position along its length. Disposed parallel to the sheet is and conductors 54, l? is an engraved chart 25 defining the field 58 over which the two contacts l9 and 23 are movable. This chart 2% is conven iently mounted. upon the same stationary support members ii and is engraved according to any desired. pattern, 6. g. with a series of horizontal and vertical co-ordinate lines corresponding to the X and Y conductors l4 and H. ternatively or additionally it may be provided with a map contour or other design. This chart, which is mounted in front of the sheet 59 for use by an operator, co-operates with a movable stylus point 2'! which is carried by arms 28, 29 forming a further part of the pan-tograph lever system 22.

The arms 2%, 24 and 223 of the pantograph lever system 22 are each pivotally connected respectively to further arms 30, 3i and 32 freely pivoted upon a fixed spindle 33 lying at right angles to and to one side of the sheet Hi and chart 26. The free ends of extensions of these arms 30, Si and 32 are rigidly interconnected by link The arms 2!, 25 and 29 are similarly connected respectively to further arms 34, 35 and 35 which are also freely pivoted upon the spindle 33 and again each have their free ends rigidly interconnected by a link 31. The resultant construction pro ides a pantograph lever system 22 in which any movement imparted to the stylus point 27 to place it in any required position within the field to will cause equivalent movement of both movable contacts 19 and 23 to maintain them in alignment with the stylus and thus to make contact with the particular X and Y conductors l4 and l? which are appropriate to the co-ordinates of the selected point.

The two contacts l9 and 23 are electrically interconnected through the lever system 22 so that the selected X and Y conductors which are respectively engaged by the contacts at any time, are connected electrically in series by such con-- tacts.

The engagement of the contacts i3- and 23 with any two selected conductors 1%, llof the-X and Y sets controls the derivation of appropriate signals representative of the particular conductors in use for transmission to a receiver device and the coding means by which such signals may be derived is illustrated and described in detail in copending patent application No. 265,468, new U. S. Patent No. 2,672,605, dated March 16, 1954. On example of such coding means will now be described with reference to Fig. 4 in which, for simplicity, it will be assumed that there are only 7 rods. M in the set of X. conductors and only T rods H in the set of Y conductors. In practice, of course, there will be, many more conductors in each set to obtain adequate resolution.

Referring now to Fig. 45, the various X conductor-s it are associated with a series of transformers Ti, T2, T3 representing respectively the successively ascending powers of the binary scale, 2, 2 and 2 he transformer Ti (corre sponding to binary power 2. has four secondary windings tic, tllb, tie and tld, the transformer T2 (corresponding to binary power 2 two secondary windings t2! and tab and the third transformer T3 (corresponding to; binary power 2 has only one secondary winding it. The various X conductors are, for the purpose of identification, serially numbered in the. binary scale as oer, 010 111 (i. e. l to 7' in the decimal scale Each conductor Hi is connected to a common' lead it? by such of the secondary windings of the transformers Tl, T2 and T3, connected in series, as associate that particular conduct with the transformers appropriate to the bin ry identh fication number of the conductor. Thus X conductor 001 is connected to the common lead it through only winding tin of transformer T5. (corresponding to 2. conductor 010 is connected to lead 50. through only winding we of transformer T2 (corresponding to 2 conductor 011 is connected to. lead 49. through winding ti?) of trans former Tl, (2) thence through winding tin of transformer Tit (2. and so on, conductor 111 being connected to. the common lead by way of a secondary winding of each transformer, namely, winding tld of transformer T9, winding of transformer winding it of transformer T3.

Each transformer Tl, T2 and a primary winding, tip, i210 and 123;) respectively. Each primary winding is separately and con tinuously energised from an oscillator or like A. C. frequencysources PS5, F82 and The respective frequencies provided by the PS5, PS2 and are distinctively eren one another and should not, for preference, near any harmonic relationship to one another. Thus transformer T! be energised at a frequency ft of, say, 1,606 (3. P. 8., transformer T2 at frequency f2 of, say, 1200 C. P. S. and. transformer T3 at frequency f3 of, say, 1 C. P. S.

Similar arrangements are provided for the Y conductors ll by means three further transformers T4, T5 and TE and common lead ill. Transformer T5 is provided with our secondary windings bill, 154?), tdc and 154d which are connected respectively to Y conductors numbered 001, 011, 101 and 111, transformer T5 is provided with two secondar windings iSa, tiih connected respectively to Y conductors 010 and and also to windings t lt; and Md of transformer T4 i511 and flip, which are energized respectively by three further oscillators or like A. C. frequency sources FS l, F85 and F86. The frequencies of operation of these sources are again arranged to be different from one another and from those of the sources FSi, F52 and FS3. Thus the frequency, f t, of source F-S4 may be 1700 C. P. S., that, it, of source F85, 1900 C. P. S. and that, it, of source Est, 2100 C. P. S.

The common leads 45, iii are connected to suitable receiving equipment by way of some convenient communication link CL which may be a cable or like conductor or a carrier wave or radio communication link.

With the arrangement described when any one of the X conductors i4 is electrically connected to any one of the Y conductors ll through the movable contacts is and 23, signals are delivered to the communication link CL, comprising a plurality of separate frequencies representative, in the particular example given, of the binary number allocation of the two X and Y conductors concerned. For example, if X conductor 011 is connected at point 2| to Y conductor 100, the frequencies transmitted over the communication link CL will be those of ii, f2 and f6 0. P. S. If, on the other hand, X conductor 110 is connected at point 22 to Y conductor 010, the frequencies transmitted over link CL vwillbe those of f2, f3 and f5 C. P. S. and

so on.

Fig. 5 illustrates schematically one form of suitable receiving means as described in greater detail in copending patent application Ser. No. 271,488. Such receiving means comprises a gridlike arrangement of two conductor sets 4-5. and

E6 resembling respectively those ofthe X and Y sets of conductors It and I? in the transmitter device of Figs. 1, 2 and 3. In this instance, however, the two sets of conductors are disposed one on each side of a sheet of electro-responsive sheet material as, preferably through a trans- "par ent chart til which is conveniently engraved in accordance with the marking of the chart 2% of the transmitter device of Figs. l-3. Each of the X, Y, receiver conductors 4 5, 45 corresponds to an individual one of the related X, Y transmitter conductors i4, ll and occupies a similar position in the grid so formed.

The marking of the sheet of electro-responsive material it at the receiver is eifected by applying a suitably high potential between the appropriate selected one of the X conductors 45 and the appropriate selected one of the Y conductors 46 which correspond respectively with the connected X and Y conductors of the transmitter device. A spark discharge, is thereby caused to take place at the point of intersection of such selected receiver conductors, such spark passing through the intervening waxed paper or other The conductors 45, it are wires of fine I V enough gauge to allow free observation of the 6 sheet and providing a corresponding visible marking.

The selective energisation of the requisite receiver conductors 45, 36 is effected by an X decoder device 5t and a Y decoder device 5| which control the application of potential from a high-tension source 52 under the control of separate and different frequency signals on leads 53H, 5312 53f3, 53ft, 53 5 and 53ft derived from a filter network 54 whose input is supplied from the communication link CL.

The decoding means for causing the received signal to provide selective energisation of the requisite X and Y grid wires of the receiver indicating device are described in detail in copending patent application Ser. No. 271,488. The filter network is may comprise a plurality of electrical filters for separating the signals of each of the six diiferent frequencies into the six individual frequency channels appropriate thereto. The three channels 53ft, 53;2, 53ft individual to the frequencies fl, f2 and 13 C. P. S. and hence appropriate to the X co-ordinates of the transmitted position are applied to the X decoder device 58 while the similarly separated frequency channels 53M, 53ft and 53ft individual to the frequencies f4, f5 and f6 and hence appropriate to the Y co-ordinates of the transmitted position are applied to the Y decoder device 5!.

The form of the X decoder device may be as shown in Fig. 6. The construction shown comprises three strips 69, iii, cc of suitable insulating material, such as mica. The first strip 60 is arranged to correspond with the first frequency, fl, i. e. with the transformer Ti of the transmitter device, the second strip 6| with the second frequency 2 or transformer T2 of the transmitter and the third strip $52 with the third frequency it or transformer T3 of the transmitter. Each strip is arranged for longitudinal movement from an off position, as indicated in full lines and towards which the strips are each urged by gravity or by springs 68, and an on position, as indicated in chain-dotted lines, by energisation of its individual electromagnetic operating solenoid or the like 63, $4 or 65. Each of the solenoids 53, 64 and E5 is selectively energised by the received signals of frequencies fl,

f2 and f3 respectively after passage of the latter through appropriate amplifying and, if necessary, rectifying means. For example, the first solenoid 63 is energised to move the strip 68 from the full line to the chain-dotted line position upon the occurrence of a signal at frequency f2 in the output from the filter netits length, and the three strips are superimposed on each other so that the second strip lid is sandwiched' between the other two strips cc and 62.

The assembled triple layer of strips 6t, 5i and 62 is interposedbetween the co-operating elec trodes t8 and is of a row of seven separate sparkgaps designated g001,lg0l0,'g01'1 97111 '(in thebinary scale); The various electrodes 68 on one side of the strip assembly are electrically con nected and joinedto one terminal of the hightension source 52 while the opposite electrodes 69 are connected individually over lea- 53 to that one of the various X receiver conductors which has the binary identification number corresponding to that of the spark gap.

vidua-l channels 53 Each of the seven holes 61 in each strip 60, Si or 62 is located adjacent to one of the spark gaps between the opposing rows of electrodes 68, B, the exact locations of the holes being such that when all three strips are in the 011 position, as shown, the holes 6'! are not aligned in any of the seven separate gaps gOOl 0111 with the result that each spark gap is effectively closed by at least one mica strip. When the first strip 68 alone is moved to the on position due to energisation of the solenoid 63 by presence of a received signal of frequency ii, only those holes 61 adjacent the gap c001 become aligned and thus open this gap to allow passage of a spark discharge across the gap, with a corresponding energisation of the X receiver conductor 45 having the identification 001. When the second strip iii alone is moved to the on position only those holes 6'! adjacent the gap 9010 will become aligned to allow a spark discharge for energising the X receiver conductor having the identification 010. Similarly when both first and second strips St, 6! are moved to the on position by the simultaneous presence of received signals of fre quencies fl and f2, the holes 67 adjacent gap @7011 will be the only ones in alignment and so on.

The Y decoder device El is of precisely similar construction for energisation of its solenoid or like strip-operating means by received signals of frequencies f4, f5 and ft.

In the operation of the system described, the stylus 21 will first be assumed to be located outside the field it of the reference system. In consequence neither of the movable contacts i9, 23 will be in engagement with any of the conductors M, H and all of the secondary windings of transformers TIT6 will be an open circuit and no signal will be delivered to the communication link CL. At the receiver, none of the solenoids of either decoder device 50, 55 will be energised and the movable strips of each will all be in the off position to close all of the spark gaps and thus ensure that no receiver conductor is energised.

If now the stylus point 2'! is moved to a position within the field H8 in order to represent the position of some object with respect to the system, the two movable contacts i9 and 23 will each be moved correspondingly to engage respectively with the particular conductor bars I l and H which represent the co-ordinates of the position indicated by the stylus point. In this way a circuit will be completed between the common leads 40, M (and hence between the ends of the communication link CL) by way of such conductors and the appropriate secondary windings of the transformers Ti T3 and Ti-T6 which represent the binary identification numbers of those conductors and will thus cause delivery to the communication link CL of the requisite frequency signals which are indicative of the contacted conductor rods.

At the receiver, the filter networks 54 separate out the transmitted frequencies into their indi- 53ft to effect energisation of the associated solenoids in the X and Y decoder devices 5i 5! and thus to cause displacement to the "on position of those strips whose -movement. is necessary to open the particular spark-gaps which are associated with the receiver conductor rods which represent the co-ordinates of the object. A circuit is thus completed from one pole of the H. T. source 52 by way of the opened X spark gap, the corresponding X receiver conductor, the intermediate spark gap through the waxed paper 48, the appropriate Y receiver 8 conductor and the opened Y spark gap to the opposite pole of the H. T. source.

lhe passage of the spark through the waxed paper at the intersection of the energised X and Y conductors causes melting of the wax over a small area around the discharge point. The waxed paper sheet as is viewed by an observer from the direction 0 under the illumination of a light source 8 and the increased translucence of the melted wax area gives to the observer the appearance on the viewed illuminated side of a darker spot on the sheet of otherwise opaque light reflecting paper. The position of this spot, as determined by the co-ordinates engraved on the transparent chart 49 through which it is observed, corresponds to the position of the stylus point 21 and so indicates the position of the objeot with respect to the rectangular grid of the reference system at the transmitter device.

Although one of the sets of the receiver conductor wires is located between the observer and the waxed paper sheet at, the choice of a suitable fine gauge for such wires permits a sufiiciently clear view of the spot to be obtained.

The above described embodiment utilising rectangular co-ordinates is clearly only one of many possible constructions and is given by way of descriptive illustration only. The arrangements described may be extensively modified within the scope of the invention.

Fig. 7 illustrates one possible modification in which instead of connecting the two X and Y transmitter conductors M, ii in series at the intersection to define the position of the object, such conductors may be connected in parallel. Referring to Fig. 7 the two movable contacts is and 23' co-ordinated with the stylus point 2? as before by mounting upon a pantograph lever system 22, are each connected directly to -earth while the two common output leads to,

di from the X and Y coding systems it, ll, which comprise multiple transformers as already described in connection with Fig. l. are connected together and taken to earth through the primary of a transformer Tl whose secondary winding is connected to the communication link CL. The connections at the receiver may be similar to those already described.

With such a modified arrangement the engagement of either X or Y movable contact it or 23' with one of the associated conductors it or it" completes the appropriate secondary circuit or circuits of the X or transformers in the coding systems it, H, as the case may the path from earth being completed back to earth by way of the movable contact it or concerned, the particular X or Y conductor id or i l engaged by that contact, the secondary windings appropriate to that conductor on one or more of the transformers within the coding systems is, ii, the appropriate common output lead is or All and the primary of the output transformer T'i. This arrangement has the advantage that a signal is transmitted to the receiver even though only one of the two movable contacts i9, 23 is in engagement with a conductor.

This modified embodiment of Fig. also illustrates a reference system of hyperbolic form and of the type well lanown in connection with radio navigation. The conductors it, i? are, this case, bent to the shape or" the various hyperbolas those in each set being, of course, confocal. it will be appreciated that, in order to determine the position of an object uniquely, the reference system must be such that no curve of either a family intersects a curve of the other family at more than one point.

Fig. 7 also illustrates an alternative mounting arrangement for the X and Y conductors. In this embodiment the X conductors M are carried upon one sheet of insulating material 52 and the Y conductors ll upon a separate sheet of insulating material #3 with the exposed contact surfaces of the two sets of conductors facing each other. This enables the movable contacts i9, 23 to be combined as a single, double-ended, structure it carried by one pair of arms of the pantograph lever system 22.

Fig. 8 illustrates a further modification in which the two sets of X and Y conductors l4" and ll" are located quite separately from each other and are no longer located relatively to each other so as to form a grid-like assembly.

To permit this arrangement, in which the X Y conductor sets are mounted in a common plane, the pantograph lever system 22' is suitably modified in its linkage arrangements to provide the requisite conjoint movement of the two movable contacts i5, 23 with respect to the sets of conductors. In this embodiment also, the engraved chart 23' against which the stylus point 31' is moved is of different size from that of the field areas it of the movable contacts is, 23, the requisite alteration of scale being effected by suitable modification of the mechanical linkages of the pantograph lever system.

Fig. 8 also illustrates a reference system of polar co-ordinates with one, the X, family of curves as co-planar concentric circular arcs and the other, the Y, family of curves as coplanar straight lines passing through a common origin which is, effectively coincident with the centres of the circular arcs of the X family.

Fig. 9 shows yet a further modification in which, although the reference system is effectively that of a system of rectangular coordinates, the various X and Y conductors comprise only two series of contact studs it, Tl engaged respectively by movable wipers l8, '19. The wiper i8 is carried upon a longitudinally slidable bar as provided at one end with a transversely disposed slot 8i within which is received a pin 82 which itself may form the movable stylus point 21 or which, alternatively, may be linked to the latter by way of a pantograph lever system. The other wiper i9 is similarly carried upon a second longitudinally slidable bar 83 also having a slot 84 disposed at right angles to the slot 8|. This second slot 84 likewise receives the pin 82. Movement of the pin 82 to any point within the field l8 will produce movement of each wiper 18, 19 to appropriate contact studs to define the X and Y co-ordinates of the pin position.

Where the reference system is that of rectangular co-ordinates, as described in connection with Figs. 1-6 or Fig. 9, the stylus point 2! may be constrained to follow a circular are centered on the origin of the system. The X and Y coordinates of any position of the stylus are then proportional respectively to the cosine and sine of the angle between the radius vector of the stylus and the X axis. An equivalent of a sine/cosine potentiometer is thus provided. "Any convenient values may be chosen for the frequencies employed to characterise the various X and Y conductors. In practice it is advisable to ensure that none of the frequencies have a harmonic relationship since if, for example, f2 equals 3 l, the f2 solenoid at the receiver may be incorrectly actuated by the third harmonic of an fl signal. Typical frequency values are the six frequencies already given but the frequencies used may clearly be of any suitable value according to the number of channels required and the type of communication link employed. Obviously the actual frequencies fl fat at the receiver need not be the same as those which are related thereto at the transmitter. They may be widely different, for example, as a result of frequencychanging during transmission over the communication link CL. I

In some cases it may be undesirable to allow the movable contact 19 or 23 to bridge adjacent transmitter conductors when passing from one to another in which case the diameter of the operative surface of the contact must be less than the width of insulation between conductors. Where such bridging is unobjectionable the interconductor insulation may be reduced to a thin film thereby increasing the number of conductors capable of being accommodated in a given size of field l8 and so increasing the resolving power of the arrangement.

I claim:

1. A system for transmitting date indicative of the position of an object with respect to a predetermined reference system of two intersecting families of curves, which comprises two sets of transmitter electrical conductors, such conductors being shaped and positioned to represent respectively said two families of curves and each conductor being insulated from all the other conductors, contact means for effecting electrical connection with any selected one transmitter conductor in each of said sets of conductors, which selected conductors are representative of those two of said curves whose intersection defines the position of the object at that moment, coding means for deriving, under the control of each of said connected transmitter conductors, a signal representative of that conductor, a receiver comprising first and second sets of receiver conductors, the individual conductors in each set corresponding to the conductors in the respective transmitting sets, decoding means for causing each of said signals to energise the receiver conductor corresponding to the transmitter conductor which is represented by that signal and reproducing means comprising an electroresponsive sheet arranged parallel to said first and second sets of receiver conductors and adapted to respond visibly at a point whose coordinates correspond to those of the individual receiver conductors one in each set which are energized at any instant by the said decoding means.

2. A system for transmitting data indicative of the position of an object with respect to a predetermined reference system of two intersecting families of curves, which comprises a transmitter having a first set of electrical conductors shaped and positioned to represent one of said two families of curves, a second set of electrical conductors shaped and positioned to represent the other of said two families of curves, each of said conductors being insulated from all other conductors, movable contact means for establishing electrical connection with that transmitter conductor in said first set and that transmitter conductor in said second set which are representative of those two of said curves whose intersection defines the position of an object at any moment, coding means controlled by said established connections between said contact means and said conductors of said first and second sets for deriving signals representing respectively the contacted conductors of said first and second sets, a receiver comprising a first set of electrical conductors one for each of and corresponding to the conductors of said first set of transmitter conductors, a second set of electrical conductors one for each of and corresponding to said conductors of said second set of transmitter conductors, decoding means for causing signals to energise selected conductors of each of said first and said second set of receiver conductors which correspond to the contacted transmitter conductors and reproducing means comprising a sheet of electro-responsive material arranged to respond visibly at a point corresponding to the intersection of said selected receiver conductors whereby the energisation of said selected receiver conductors provides an indication of the position of said object at any moment.

3. A system according to claim 2 in which said first and second sets of transmitter conductors are disposed respectively on opposite sides of an insulating sheet and which includes separate contact means for each of said conductor sets, said contact means being mechanically interconnected for conjoint movement.

4. A system according to claim 2 in which said first and second sets of transmitter conductors are mounted upon opposing parallel surfaces of separate insulating members and in which said contact means is constituted by a single element with double contact making surfaces operative between said opposing surfaces.

5. A system according to claim 2 in which said first and second sets of transmitter conductors are disposed in coplanar and spatially separated relationship with individually movable contact means for each of said sets of transmitter conductors and which includes a stationary chart bearing a representation of said reference system, a stylus member movable with respect to said stationary chart for indicating an object position with respect to said reference system and mechanical linkage means interconnecting said individual movable contact means and said stylus member for conjoint movement.

6. A system according to claim 2 which includes circuit connections by which said movable contact means connects the selected conductor of said first set of transmitter conductors in series with the selected conductor of said second set of transmitter conductors to complete a circuit of which each conductor forms a part.

'7. A system according to claim 2 which includes circuit connections by which said movable contact means connects said selected conductor of said first and second sets of transmitter con- 12 ductors in parallel with one another to complete two electric circuits of which said conductors respectively form parts.

8. A system according to claim 2 wherein said first and second sets of transmitter conductors define a reference system of rectangular co-ordinates and which includes means for constraining said contact means to follow a circular arc of movement centred on the origin of said reference system.

9. A system accordingto claim 2 wherein said receiver comprises means for positioning said first and second sets of receiver conductors upon opposite sides of said electro-responsive sheet in correct relationship to define said reference system and a source of electric potential, said decoding means serving to connect said source of potential between a selected conductor of said first set and a selected conductor of said second set to produce a responsive marking on said electro-responsive sheet at the point of intersection of said selected conductors.

in. A system according to claim 2 wherein said receiver comprises a sheet of waxed paper, means for positioning said first and second sets of receiver conductors upon opposite sides of said sheet in correct relationship to define said reference system, a source of electric potential and means for illuminating one side of said sheet, said decoding means serving to connect said source of potential between a selected conductor of said first set and a selected conductor of said second set to produce a spark discharge through said sheet at the point of intersection of said selected conductors for melting said wax to alter the coefficient of light reflection of said sheet at said point.

11. A system according to claim 2 wherein the electro-responsive material is arranged between the first and second sets of receiver conductors, and is visibly responsive by the burning effect produced by an electrical discharge between said selected receiver conductors of the first and second sets.

References Cited in the file of this patent UNITED STATES PATENTS Name Date Ghio Oct. 29, 1918 Parker et al. July 5, 1921 Lee Aug. 20, 1929 Wensley Dec. 30, 1930 Tarbox July 3, 1934 Harrison Sept. 28, 1937 Hulle'gard Dec. 5, 1939 Kinkead et al. Oct. 5, 1948 Number 

